JP6338518B2 - Micro bubble generator - Google Patents

Description

  The present invention relates to a microbubble generator that manufactures microbubbles (fine bubbles), which are widely used, with a simple configuration.

Microbubbles are microbubbles that are much smaller than ordinary bubbles, but they have various characteristics that are not found in large bubbles. They have extremely low ascent speed, are easily dissolved in water, adsorb to substances in water, and bubbles are hard to break. Etc. are known.
For this reason, the use of microbubbles is spreading in various fields such as wastewater treatment, cleaning, beauty, and aquaculture.
There are nine known microbubble generation mechanisms: a crushing method, a cavitation method, a supersaturated precipitation method, a turbulent flow method, a fine pore method, a fixed dissolution method, an electrolytic method, a chemical method, and a reduction method.

  Conventionally, large bubbles that cannot be micro-sized by a micro-bubble generator are sent together with the micro-bubbles, so bumping is likely to occur. In addition, costly gas microbubbles such as carbon dioxide gas waste gas that could not be microbubbled. However, a fine bubble forming apparatus that solves this problem is known (see Patent Document 1).

In this known technique, in a circulation path of a microbubble generator composed of a storage tank, a bubble refining means, and a pressurized liquid pump, a pressure adjusting tank having a microbubble generating nozzle installed thereon is provided, and an upper part of the pressure adjusting tank This is a fine bubble forming device that floats and separates large-sized bubbles in a space, sucks the gas in the upper space, and returns the bubbles as microbubbles from the microbubble generating nozzle into the liquid in the pressure adjusting tank.
In this fine bubble forming apparatus, since the pressure adjusting tank is provided in the circulation path of the microbubble generator, the apparatus cannot be miniaturized. Therefore, the development of a microbubble generator that produces microbubbles with a simpler configuration has been desired.

JP 2011-206689 A

  An object of this invention is to provide the microbubble generator which manufactures the microbubble which the application field has expanded with a simple structure.

The microbubble generator of the present invention includes a storage tank filled with a liquid, a gas generator, a large bubble gas recovered from a holder in the storage tank, and a Y joint that joins the gas from the gas generator. A first valve that adjusts the amount of gas supplied from the Y joint, a two-fluid nozzle that mixes the gas from the first valve and the return liquid from the storage tank to form a gas-liquid mixed fluid, A pressurized liquid pump that sucks and pushes the gas-liquid mixed fluid formed by the two-fluid nozzle, a pressure-feeding tube that pumps the gas-liquid mixed fluid from the pressurized liquid pump to the storage tank, and a gas-liquid in the pressure-feeding tube A second valve that releases the mixed fluid to normal pressure, and a holder that includes a means for holding a porous filter having fine holes in the storage tank and collecting large bubbles.
The holder covers the porous filter and forms a hollow case so that a large bubble is sucked into the two-fluid nozzle through the Y joint and the first valve again with a gas return tube. Inhale.

  The microbubble generator of the present invention has very few equipments to be used, a pump, a two-fluid nozzle, only two porous filters and tubes for two valves, has a low manufacturing cost, and is suitable for mass production. The feature is that there is no failure other than that, and the quantity and quality of microbubbles that can be produced has the effect of contributing to the industry.

It is a schematic block diagram of the microbubble generator of this invention. It is sectional drawing of a 2 fluid nozzle. It is sectional drawing of a porous filter.

One embodiment of the microbubble generator of the present invention will be described below with reference to the accompanying drawings.
As shown in the schematic configuration diagram of FIG. 1, the microbubble generator of the present invention includes a storage tank 2 filled with a liquid 1 such as water or hot water, a gas generator 3 such as CO 2, and the storage tank 2. A Y-joint that joins the gas return side 5 from the gas return tube 4 of the large bubble gas recovered from the holder 16 and the gas injection side 7 from the air supply tube 6 that supplies the gas from the gas generator 3 8, a first valve 9 that adjusts the amount of gas supplied from the Y joint 8, and a return liquid 1 in a circulation tube 10 that circulates the gas from the first valve 9 and the liquid 1 from the storage tank 2. A two-fluid nozzle 11 that mixes to form a gas-liquid mixed fluid, a pressurized liquid pump 12 that sucks and pushes the gas-liquid mixed fluid formed by the two-fluid nozzle 11, and a gas from the pressurized liquid pump 12. Liquid mixed fluid is pumped to the storage tank 2 A feed tube 13, the second valve 14 to release the gas-liquid mixed fluid of the piezoelectric feed tube 13 to the atmospheric pressure, is connected to said pumping tube, a porous filter 15 is held in the storage tank, the storage tank 2 A porous filter 15 having fine holes therein is held, and a case 20 for collecting large bubbles generated on the original side of the porous filter 15 and a holder 16 having a gas return tube 4 are configured.

The gas generator 3 includes a gas cylinder such as a gas contained in a pressure vessel.
The Y joint 8 is installed to suck in air (when a large bubble gas is not recovered) and various gases.
The first valve 9 is for determining the amount of air or gas to be sucked.
As shown in FIG. 2, the two-fluid nozzle 11 has a nozzle rod 18 fitted to the nozzle outer tube 17, and the tip of the nozzle rod 18 is positioned on the tapered surface of the nozzle chamber 19 of the nozzle outer tube 17. When the return liquid 1 from the circulation tube 10 flows strongly, a gas suction force to the first valve 9 is generated. In the nozzle chamber 19, liquid, air, and gases are appropriately mixed, and turbulent flow and shearing occur due to the orifice effect. In the two-fluid nozzle 11, the state where the gas and the liquid coexist is made a turbulent flow, and the gas is separated into bubbles so as to be separated.

Since the pressurized liquid pump 12 requires torque, it is necessary to select a model that is resistant to torque, and a pressurized type is essential and must be self-contained. The gas-liquid mixed fluid from the two-fluid nozzle 11 drawn into the pressurized liquid pump 12 has higher air and gas solubility than the steady state due to the pressurized liquid pump 12 being pressurized. In the pressurized liquid pump 12, shearing and pressurization are repeated to grow into bubbles with the bubble core as the center.
The pressure feeding tube 13 pressure-feeds the gas-liquid mixed fluid from the pressurized liquid pump 12 to the storage tank 2.
The second valve 14 releases the gas-liquid mixed fluid in the pressure feeding tube 13 to normal pressure. Since the second valve 14 leads to an appropriate clearance and the pressure is returned to normal pressure, the dissolved gas becomes bubbles and exits to the storage tank 2.

The porous filter 15, which was weakly bound to the fine particles and fibers such as glass and metal ceramic, air and gas that can not be dissolved in the original side becomes large bubbles, microbubbles are fixed amount released at the tip.
As shown in FIG. 3, the holder 16 covers the original side of the porous filter 15 and sucks large bubbles generated on the original side of the porous filter 15 by making the case 20 hollow at the center. By letting the two-fluid nozzle 11 to suck again from the outlet 21 through the Y joint 8 and the first valve 9 through the gas return tube 4, air and gases can be used without waste.

Next, the operation of the microbubble generator of the present invention will be described below based on the attached drawings.
As shown in FIG. 1, the liquid 1 is sent from the lower part of the storage tank 2 to the two-fluid nozzle 11 through the circulation tube 10, and the large bubble gas from the holder 16 is returned to the Y joint 8 by the gas return tube 4. On the other hand, the fresh gas is sent from the gas generator 3 to the gas injection side 7 of the Y joint 8 through the air supply tube 6 while the return gas and the fresh gas are merged, and the first valve 9 is connected from the Y joint 8 to the side 5. To the two-fluid nozzle 11.
As shown in FIG. 2, the two-fluid nozzle 11 has a nozzle rod 18 fitted to the nozzle outer tube 17, and the tip of the nozzle rod 18 is positioned on the tapered surface of the nozzle chamber 19 of the nozzle outer tube 17. When the return liquid 1 from the circulation tube 10 flows strongly, a gas suction force to the first valve 9 is generated. In the nozzle chamber 19, liquid, air, and gases are appropriately mixed to form a gas-liquid mixed fluid.

When the gas-liquid mixed fluid pushed out from the pressurized liquid pump 12 enters the pressure feed tube 13 and returns to a steady state and becomes a supersaturated state, cavitation is strongly generated, and dissolved air and gas are deposited. At that time, the gas-liquid mixed fluid boils.
The second valve 14 directly leads to an appropriate clearance and returns to normal pressure, so that the dissolved gas comes out as bubbles into the storage tank 2.
At this stage, since there are few gases that become microbubbles, the air and gas that could not be dissolved on the original side by being led to the porous filter 15 become large bubbles, and a certain amount of microbubbles are released at the tip.

Application examples 1. Beauty effect generated by discharge into warm liquid such as micro bubble bath. 2. Deodorizing effect and cleaning effect obtained by blowing cleaning liquid and deodorizing liquid with microbubbles. Cleaning effect for aircraft and ship skins and pipes (including anti-corrosion measures)
4). 4. Energy saving effect to increase the combustion effect by combining hydrogen and oxygen into fuel and other micro bubbles. Humidity control effect of applying liquid as warm mist and blowing strongly into microbubbles

DESCRIPTION OF SYMBOLS 1 Liquid 2 Reservoir 3 Gas generator 4 Gas return tube 5 Gas return side 6 Supply tube 7 Gas injection side 8 Y joint 9 First valve 10 Circulation tube 11 2 Fluid nozzle 12 Pressurized liquid pump 13 Pressure feed tube 14 Second Valve 15 Porous filter 16 Holder 17 Nozzle outer cylinder 18 Nozzle rod 19 Nozzle chamber 20 Case 21

Claims (2)

A storage tank filled with a liquid, a gas generator, a large bubble gas recovered from a holder in the storage tank, a Y joint for merging the gas from the gas generator, and supply of gas from the Y joint A first valve that adjusts the amount; a two-fluid nozzle that forms a gas-liquid mixed fluid by mixing the gas from the first valve and the liquid returned from the storage tank through a circulation tube ; and the two fluids A pressurized liquid pump that sucks and pushes the gas-liquid mixed fluid formed by the nozzle, a pressure-feeding tube that pumps the gas-liquid mixed fluid from the pressurized liquid pump to the storage tank, and a gas-liquid mixed fluid of the pressure-feeding tube A porous valve connected to the pumping tube and held in the storage tank, and a porous filter having micropores in the storage tank , Original In microbubble generating apparatus characterized by being configured large bubbles generated from a holder having a case and a gas return tube to recover. The holder sucks large bubbles generated on the original side of the porous filter by covering the original side of the porous filter with a case having a hollow center, and the Y joint, 2. The microbubble generator according to claim 1, wherein the two fluid nozzles are sucked through one valve.

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